CN114277277A - AlN/Al particle reinforced magnesium-aluminum rare earth based composite material and preparation method thereof - Google Patents

Abstract

The invention discloses an AlN/Al particle reinforced magnesium-aluminum rare earth based composite material, which comprises the following components in percentage by mass: 99-99.9% of a magnesium matrix alloy and 0.1-1% of AlN/Al composite particles, the magnesium matrix alloy including Al: 4.17%, Mn: 0.36%, Si: 0.02 percent of RE, 3.99 percent of RE and the balance of Mg, wherein the RE is 50Ce-26La-15Nd-3 Pr. The invention also discloses a preparation method of the AlN/Al particle reinforced magnesium-aluminum rare earth based composite material. According to the invention, by combining the mechanical ball milling, mechanical stirring and ultrasonic stirring, the combustion or oxidation of particles can be avoided, the problem that AlN particles are difficult to wet with the magnesium matrix alloy is solved, and the grain size of the magnesium matrix alloy is obviously refined; the obtained composite material has compact structure, no obvious interface reaction, excellent metallurgical quality and no obvious defect or impurity.

Description

AlN/Al particle reinforced magnesium-aluminum rare earth based composite material and preparation method thereof

Technical Field

The invention belongs to the technical field of metal matrix composite materials, and particularly relates to an AlN/Al particle reinforced magnesium-aluminum rare earth matrix composite material and a preparation method thereof.

Background

The magnesium alloy is used as the lightest metal structure material, has the advantages of high specific strength, good cutting performance, excellent electromagnetic shielding performance and the like, and has extremely wide application prospect in the aspects of automobiles, aerospace, electronic industry and the like. However, the magnesium alloy has a close-packed hexagonal structure, and as-cast structure grains are coarse, and the strength and plasticity are poor, so that the wide application of the magnesium alloy is greatly limited. According to Hall-Petch formula (σ ═ σ%₀+kd^-1/2) The mechanical property of the magnesium alloy can be obviously improved by refining the grain size of the magnesium alloy. Grain refinement also significantly reduces the hot cracking propensity and casting defects of the casting, improving the size and dispersion of the second phase. Currently, the most effective grain refining element in magnesium alloys is Zr (zirconium). However, since Zr element is easily peritectic with Al element to form Al3Zr, it cannot be used for grain refinement of Al-containing magnesium alloy.

Reportedly of nanometer or micrometer sizeThe ceramic particles, such as silicon carbide (SiC), titanium carbide (TiC), aluminum nitride (AlN) and the like, have the advantages of high strength, high elastic modulus, high thermal stability and the like, and can be used as a heterogeneous nucleation matrix of an alpha-Mg matrix to effectively refine the grain size of the magnesium alloy. Wherein, the AlN particles have a close-packed hexagonal structure which is the same as that of Mg, and the crystallography matching performance is good; meanwhile, AlN particles are not easy to generate interface reaction with the magnesium matrix, the AlN/Mg interface bonding strength is high, and the strength, Young modulus, wear resistance, high-temperature creep property and the like of the magnesium alloy can be simultaneously increased. But the AlN particles (especially nano-scale particles) have poor wettability with the magnesium matrix when the melting temperature is lower than 720 ℃; the AlN particles are directly added by an external method, so that the particles are easy to agglomerate, and the AlN particles are not easy to be uniformly dispersed in a melt, thereby influencing the grain refining effect of the AlN particles. By endogenously adding Mg₃N₂AlN particles can be generated in situ, but AlN particles are relatively coarse in size and difficult to control. In order to improve the wettability of AlN particles and magnesium melt, effectively improve the dispersion characteristics of the particles and obviously refine grains, a preparation technology of an AlN particle reinforced magnesium-based composite material and a grain refining method thereof need to be researched, and the AlN particle reinforced magnesium-lithium based composite material with excellent comprehensive performance is prepared.

Disclosure of Invention

The present invention is directed to solving, at least to some extent, one of the technical problems in the related art. Therefore, the invention mainly aims to provide an AlN/Al particle reinforced magnesium-aluminum-rare earth-based composite material and a preparation method thereof, and aims to solve the problem that the conventional AlN particles are poor in wettability and cannot realize uniform and stable dispersion, so that the grain size of the composite material is large.

The purpose of the invention is realized by the following technical scheme:

in a first aspect, an AlN/Al particle-reinforced magnesium-aluminum-rare earth-based composite material comprises the following components in percentage by mass: 99-99.9% of a magnesium matrix alloy and 0.1-1% of AlN/Al composite particles, the magnesium matrix alloy including Al: 4.17%, Mn: 0.36%, Si: 0.02 percent of RE, 3.99 percent of RE and the balance of Mg, wherein the RE is 50Ce-26La-15Nd-3 Pr.

Preferably, wherein the AlN/Al composite particles include AlN particles and Al particles, the AlN particles have a particle size of 40nm, the Al particles have a particle size of 10 μm, and the AlN particles and the Al particles have a mass ratio of 3: 1.

in a second aspect, the preparation method of the AlN/Al particle-reinforced magnesium-aluminum rare earth-based composite material comprises the following steps:

1) preparation of AlN/Al composite particles: mixing and ball-milling the AlN particles and the Al particles in percentage by mass in a star-shaped ball mill in a glove box protected by pure argon, and coating the ball-milled mixed material with aluminum foil after the ball-milling to prepare AlN/Al composite particles;

2) smelting and casting the magnesium-based composite material: adding the AlN/Al composite particles obtained in the step 1) into a magnesium-aluminum rare earth melt, and primarily dispersing the AlN/Al composite particles by adopting mechanical stirring to obtain a composite melt; and after the temperature is raised to the liquidus temperature, further dispersing the composite melt by adopting ultrasonic waves, standing and preserving the temperature, and performing water condensation to solidify to obtain the AlN/Al particle reinforced magnesium-aluminum-rare earth based composite material.

Preferably, when the AlN particles and the Al particles are mixed and ball-milled, the ball-milling rotating speed is 80-120rpm, the ball-milling time is 4-12h, and the mixture is kept stand for 24-48h after the ball-milling is finished.

Preferably, the magnesium-aluminum rare earth melt is prepared by the following steps:

at a volume ratio of 99: 1 CO₂And SF₆Under the protection of mixed gas, magnesium-based alloy is put into a crucible and heated along with a smelting furnace to 680-780 ℃ until the magnesium-based alloy is completely melted, the magnesium-based alloy is uniformly stirred, and scum on the surface of the melt is scraped to obtain the magnesium-aluminum-rare earth melt.

Preferably, when the AlN/Al composite particles are added, the temperature of the magnesium-aluminum rare earth melt is reduced to 610-650 ℃, the mechanical stirring speed is 300-1000rpm, and the stirring time is 5-10 min.

Preferably, wherein the mechanical agitation is: stirring back and forth for 2-5min at the middle upper part and the lower part of the crucible, and after the AlN/Al composite particles are completely immersed into the magnesium-aluminum rare earth melt, stirring at a fixed point for 3-5min at the middle position of the crucible.

Preferably, after the AlN/Al composite particles are added, the AlN/Al composite particles coated with the aluminum foil are pressed to the bottom of the crucible for 30-100s by using a stirring spoon until the AlN/Al composite particles are released into the magnesium-aluminum rare earth melt and are completely coated by the magnesium-aluminum rare earth melt.

Preferably, the AlN/Al composite particles are added into the magnesium-aluminum rare earth melt and are mechanically stirred uniformly to obtain the composite melt, the temperature of the composite melt is raised to 680-720 ℃, the composite melt is dispersed by adopting ultrasonic waves, the power of the ultrasonic waves is 150-300W, and the dispersion time is 5-10 min.

Preferably, after the composite melt is uniformly dispersed by ultrasonic waves, scum on the surface of the composite melt is removed, the temperature of the composite melt is kept at 700 ℃, and after standing for 5-20min, water is condensed and solidified.

Compared with the prior art, the invention has at least the following advantages:

according to the preparation method of the AlN/Al particle reinforced magnesium-aluminum rare earth based composite material, firstly, AlN particles and Al particles are pre-dispersed through mechanical ball milling, the exposed surface of the AlN particles is reduced, and the surface water vapor and oxygen content are reduced, so that the wettability of the AlN particles and a magnesium melt is improved, and the uniform dispersion of the AlN particles is promoted; then, mechanical stirring is adopted to add the AlN/Al composite particles when the temperature is slightly higher than the semi-solid temperature of the magnesium matrix alloy, so that the burning loss and the oxidation of the AlN/Al composite particles are avoided, and the formation of impurities is reduced; and finally, carrying out ultrasonic dispersion stirring on the AlN/Al composite particles and the composite melt at the liquidus temperature, and regulating and controlling the standing time after stirring to prepare the AlN/Al particle reinforced magnesium-aluminum-rare earth-based composite material with small grain size, good interface combination and no obvious interface reaction.

Drawings

FIG. 1 is a process flow diagram of a method for preparing the AlN/Al particle-reinforced Mg-Al rare earth based composite material of example 2;

FIG. 2 is a metallographic microstructure of an as-cast alloy of magnesium aluminum rare earth alloy AE44 without added AlN composite particles;

FIG. 3 is a metallographic microstructure of a composite material prepared in example 1;

FIG. 4 is a metallographic microstructure of a composite material prepared in example 2;

FIG. 5 is a metallographic microstructure of a composite material prepared in example 3;

FIG. 6 is a metallographic microstructure of a composite material prepared in example 4.

Detailed Description

The present invention will be further described with reference to the following drawings and examples, which are illustrative only and not intended to be limiting, and the scope of the present invention is not limited thereby.

When an amount, concentration, or other value or parameter is expressed as a range, preferred range, or upper and lower limit of the preferred value, it is to be understood that any range where any pair of upper limit or preferred value and any lower limit or preferred value of the range is combined is specifically disclosed, regardless of whether the range is specifically disclosed. Unless otherwise indicated, numerical range values set forth herein are intended to include the endpoints of the range, and all integers and fractions within the range.

All percentages, parts, ratios, etc. herein are by weight unless otherwise indicated.

The materials, methods, and examples herein are illustrative and, unless otherwise specified, should not be construed as limiting

The magnesium base alloy, AlN and Al adopted in the embodiment of the invention are commercial products, wherein the magnesium base alloy adopts commercial magnesium-aluminum rare earth alloy AE44 as a base; wherein the AlN particles are nanoparticles which act as reinforcement; the commercial magnesium-aluminum rare earth alloy AE44 comprises the following chemical components in percentage by weight: 4.17% Al, 0.36% Mn, 0.02% Si, 3.99% RE (RE ═ 50Ce-26La-15Nd-3Pr), with the remainder Mg; the particle size of the AlN particles is 40nm (purity is more than 99.9 percent) and the particles are spherical; the particle size of the Al particles was 10 μm and the purity was > 99.90%.

The metallographic microscope adopted in the embodiment of the invention is OLYMPUS PMG 3;

example 1

The preparation method of the AlN/Al particle reinforced magnesium-aluminum rare earth based composite material provided by the invention comprises the following steps:

1) selection of magnesium matrix and reinforcement. Commercial magnesium-aluminum rare earth alloy AE44 is used as a magnesium matrix, and nano ceramic AlN particles are used as a reinforcement. The magnesium-aluminum rare earth alloy AE44 comprises the following chemical components in percentage by weight: 4.17% Al, 0.36% Mn, 0.02% Si, 3.99% RE (RE ═ 50Ce-26La-15Nd-3Pr), with the remainder Mg; the particle size of the AlN particles is 40nm (purity is more than 99.9 percent) and the particles are spherical; wherein the grain diameter of the Al particles is 10 μm, and the purity is more than 99.90%;

2) preparation of AlN/Al composite particles: in a glove box protected by pure argon, mixing and ball-milling AlN particles and Al particles in a mass ratio of 3:1 in a star-shaped ball mill, specifically, performing positive and negative rotation alternation for 30min at an interval time of 10min at a ball-milling rotation speed of 100rpm for 12h, standing for 24h after ball-milling is completed, and coating a mixed material subjected to ball-milling standing by using an aluminum foil to obtain AlN/Al composite particles coated by the aluminum foil;

3) smelting and casting the magnesium-based composite material: at a volume ratio of 99: 1 CO₂And SF₆Under the protection of mixed gas, 1.5kg of magnesium-aluminum rare earth alloy AE44 is placed in a crucible to be heated along with a smelting furnace, the temperature is raised to 720 ℃ until the mixture is completely melted, the mixture is uniformly stirred, and scum on the surface of the melt is scraped to obtain a magnesium-aluminum rare earth melt; then cooling the magnesium-aluminum rare earth melt to 610 ℃, adding the aluminum foil-coated AlN/Al composite particles obtained in the step 2) into the magnesium-aluminum rare earth melt according to 0.5 mass percent of the magnesium-aluminum rare earth alloy AE44, and pressing the aluminum foil-coated AlN/Al composite particles to the bottom of the crucible for 100s by using a stirring spoon in the adding process until the AlN/Al composite particles are released into the magnesium-aluminum rare earth melt and are completely wrapped by the magnesium-aluminum rare earth melt; mechanically dispersing the AlN/Al composite particles into the magnesium-aluminum-rare earth melt by adopting a blade type stirring paddle, wherein the stirring speed is 1000rpm, mechanically stirring the AlN/Al composite particles back and forth at the middle upper part and the lower part of a crucible for 2min during mechanical stirring, and after the AlN/Al composite particles are completely immersed into the magnesium-aluminum-rare earth melt, stirring the AlN/Al composite particles at a fixed point in the middle of the crucible for 3min to uniformly disperse the AlN/Al composite particles into the magnesium-aluminum-rare earth melt to obtain a composite melt; after the mechanical stirring is finished, the temperature of the composite melt is raised to 6Placing the preheated ultrasonic stirrer in the composite melt at 80 ℃, immersing an ultrasonic stirring head in a position 4-5cm above the liquid level, wherein the power is 150W, and the dispersion time is 10 min; and after the composite melt is uniformly dispersed by ultrasonic waves, removing floating slag on the surface of the composite melt, raising the temperature of the composite melt to 700 ℃, standing for 5min, and then condensing and solidifying water to obtain the AlN/Al particle reinforced magnesium-aluminum-rare earth based composite material.

This example characterizes the structure of the AlN/Al particle-reinforced Mg-Al-RE matrix composite, and as shown in FIG. 3, the crystal grain size of the composite prepared by adding 0.5% AlN/Al composite particles is about 297.6 μm.

Example 2

The preparation method of the AlN/Al particle reinforced magnesium-aluminum rare earth based composite material provided by the invention comprises the following steps:

1) selection of magnesium matrix and reinforcement. Commercial magnesium-aluminum rare earth alloy AE44 is used as a magnesium matrix, and nano ceramic AlN particles are used as a reinforcement. The magnesium-aluminum rare earth alloy AE44 comprises the following chemical components in percentage by weight: 4.17% Al, 0.36% Mn, 0.02% Si, 3.99% RE (RE ═ 50Ce-26La-15Nd-3Pr), with the remainder Mg; the particle size of the AlN particles is 40nm (purity is more than 99.9 percent) and the particles are spherical; wherein the grain diameter of the Al particles is 10 μm, and the purity is more than 99.90%;

2) preparation of AlN/Al composite particles: mixing and ball-milling the AlN particles and the Al particles in a mass ratio of 3:1 in a glove box protected by pure argon in a star-shaped ball mill; specifically, the ball mill alternately performs positive and negative rotation for 30min with an interval time of 10min, the ball milling rotation speed is 80rpm, the ball milling time is 12h, the ball milling is completed and then stands for 32h, and after the standing is completed, aluminum foil is adopted to coat the mixed material subjected to ball milling and standing to obtain aluminum foil coated AlN/Al composite particles;

3) smelting and casting the magnesium-based composite material: at a volume ratio of 99: 1 CO₂And SF₆Under the protection of mixed gas, 1.5kg of magnesium-aluminum rare earth alloy AE44 is placed in a crucible to be heated along with a smelting furnace, the temperature is raised to 720 ℃ until the mixture is completely melted, the mixture is uniformly stirred, and scum on the surface of the melt is scraped to obtain a magnesium-aluminum rare earth melt; then diluting the magnesium and the aluminumAfter the temperature of the soil melt is reduced to 640 ℃, adding the aluminum foil coated AlN/Al composite particles obtained in the step 2) into the magnesium-aluminum rare earth melt according to 1.0 mass percent of the magnesium-aluminum rare earth alloy AE44, and pressing the aluminum foil coated AlN/Al composite particles to the bottom of the crucible for 30s by using a stirring spoon until the AlN/Al composite particles are released into the magnesium-aluminum rare earth melt and are completely coated by the magnesium-aluminum rare earth melt; mechanically dispersing the AlN/Al composite particles into the magnesium-aluminum-rare earth melt by adopting a blade type stirring paddle, wherein the stirring speed is 500rpm, mechanically stirring the AlN/Al composite particles back and forth at the middle upper part and the lower part of a crucible for 5min during mechanical stirring, and after the AlN/Al composite particles are completely immersed into the magnesium-aluminum-rare earth melt, stirring the AlN/Al composite particles at a fixed point in the middle of the crucible for 5min to uniformly disperse the AlN/Al composite particles into the magnesium-aluminum-rare earth melt to obtain a composite melt; after the mechanical stirring is finished, heating the composite melt to 680 ℃, placing a preheated ultrasonic stirrer in the composite melt, immersing an ultrasonic stirring head at a position 4-5cm above the liquid level, wherein the power is 300W, and the dispersion time is 5 min; and after the composite melt is uniformly dispersed by ultrasonic waves, removing floating slag on the surface of the composite melt, raising the temperature of the composite melt to 700 ℃, standing for 5min, and then condensing and solidifying water to obtain the AlN/Al particle reinforced magnesium-aluminum-rare earth based composite material.

In this example, the structure of the prepared AlN/Al particle-reinforced magnesium-aluminum-rare-earth-based composite material is characterized, and when 1% of AlN/Al composite particles are added to the magnesium-aluminum-rare-earth alloy AE44, the microstructure of the magnesium-based composite material is compact, has no obvious defects and impurities, and has excellent metallurgical quality. As shown in fig. 4, the grain size of the material is further refined to about 194.7 μm. Meanwhile, it can be seen that the grain refining effect of the composite material becomes more significant as the content of the AlN/Al composite particles increases.

Example 3

The preparation method of the AlN/Al particle reinforced magnesium-aluminum rare earth based composite material provided by the invention comprises the following steps:

1) selection of magnesium matrix and reinforcement. Commercial magnesium aluminum rare earth alloy AE44 is used as a matrix, and nano ceramic AlN particles are used as a reinforcement. The magnesium-aluminum rare earth alloy AE44 comprises the following chemical components in percentage by weight: 4.17% Al, 0.36% Mn, 0.02% Si, 3.99% RE (RE ═ 50Ce-26La-15Nd-3Pr), with the remainder Mg; the particle size of the AlN particles is 40nm (purity is more than 99.9 percent) and the particles are spherical; wherein the grain diameter of the Al particles is 10 μm, and the purity is more than 99.90%;

2) preparation of AlN/Al composite particles: in a glove box protected by pure argon, mixing and ball-milling the AlN particles and the Al particles in a mass ratio of 3:1 in a star-shaped ball mill, and then coating the ball-milled mixed material with aluminum foil after the ball milling is finished; specifically, the ball mill alternately performs positive and negative rotation for 30min with an interval time of 10min, the ball milling rotation speed of 120rpm and the ball milling time of 4h, stands for 36h after the ball milling is completed, and adopts aluminum foil to coat the mixed material subjected to ball milling and standing after the standing is completed to obtain aluminum foil coated AlN/Al composite particles;

3) smelting and casting the magnesium-based composite material: at a volume ratio of 99: 1 CO₂And SF₆Under the protection of mixed gas, 1.5kg of magnesium-aluminum rare earth alloy AE44 is placed in a crucible to be heated along with a smelting furnace, the temperature is raised to 720 ℃ until the mixture is completely melted, the mixture is uniformly stirred, and scum on the surface of the melt is scraped to obtain a magnesium-aluminum rare earth melt; then cooling the magnesium-aluminum rare earth melt to 650 ℃, adding the aluminum foil-coated AlN/Al composite particles obtained in the step 2) into the magnesium-aluminum rare earth melt according to 0.5 mass percent of the magnesium-aluminum rare earth alloy AE44, pressing the aluminum foil-coated AlN/Al composite particles to the bottom of the crucible for 60s by using a stirring spoon until the AlN/Al composite particles are released into the magnesium-aluminum rare earth melt and are completely coated by the magnesium-aluminum rare earth melt; mechanically dispersing the AlN/Al composite particles into the magnesium-aluminum-rare earth melt by adopting a blade type stirring paddle, wherein the stirring speed is 1000rpm, mechanically stirring the AlN/Al composite particles back and forth at the middle upper part and the lower part of a crucible for 4min during mechanical stirring, and after the AlN/Al composite particles are completely immersed into the magnesium-aluminum-rare earth melt, stirring the AlN/Al composite particles at a fixed point in the middle of the crucible for 4min to uniformly disperse the AlN/Al composite particles into the magnesium-aluminum-rare earth melt to obtain a composite melt; after the mechanical stirring is finished, heating the composite melt to 700 ℃, placing a preheated ultrasonic stirrer in the composite melt, immersing an ultrasonic stirring head in a position 4-5cm above the liquid level, wherein the power is 150W, and the dispersion time is 10 min; after the composite melt is dispersed uniformly by ultrasonic wave, removing floating slag on the surface of the composite melt, and repeatingAnd (3) raising the temperature of the fused mass to 700 ℃, standing for 15min, and then condensing water to obtain the AlN/Al particle reinforced magnesium-aluminum rare earth based composite material.

In this example, the structure of the prepared AlN/Al particle-reinforced magnesium-aluminum-rare-earth-based composite material is characterized, as shown in fig. 5, after 1% of AlN/Al composite particles are added to the magnesium-aluminum-rare-earth alloy AE44 and the mixture is left standing for 15min, the grain size of the composite material is still significantly fine, which is about 376.0 μm, compared with the particle-free magnesium-aluminum-rare-earth alloy AE 44; meanwhile, it can be found that the effect of grain refinement of the AlN/Al particles is gradually reduced as the standing time is prolonged, as compared with example 1.

Example 4

The preparation method of the AlN/Al particle reinforced magnesium-aluminum rare earth based composite material provided by the invention comprises the following steps:

1) selection of magnesium matrix and reinforcement. Commercial magnesium aluminum rare earth alloy AE44 is used as a matrix, and nano ceramic AlN particles are used as a reinforcement. The magnesium-aluminum rare earth alloy AE44 comprises the following chemical components in percentage by weight: 4.17% Al, 0.36% Mn, 0.02% Si, 3.99% RE (RE ═ 50Ce-26La-15Nd-3Pr), with the remainder Mg; the particle size of the AlN particles is 40nm (purity is more than 99.9 percent) and the particles are spherical; wherein the grain diameter of the Al particles is 10 μm, and the purity is more than 99.90%;

2) preparation of AlN/Al composite particles: in a glove box protected by pure argon, mixing and ball-milling the AlN particles and the Al particles in a mass ratio of 3:1 in a star-shaped ball mill, and then coating the ball-milled mixed material with aluminum foil after the ball milling is finished; specifically, the ball mill alternately performs positive and negative rotation for 30min with an interval time of 10min, the ball milling rotation speed is 100rpm, the ball milling time is 8h, the ball milling is completed and then stands for 48h, and after the standing is completed, aluminum foil is adopted to coat the mixed material subjected to ball milling and standing to obtain aluminum foil coated AlN/Al composite particles;

3) smelting and casting the magnesium-based composite material: at a volume ratio of 99: 1 CO₂And SF₆Under the protection of mixed gas, 1.5kg of magnesium-aluminum rare earth alloy AE44 is placed in a crucible to be heated along with a smelting furnace, the temperature is raised to 720 ℃ until the mixture is completely melted, the mixture is uniformly stirred, and the surface of the melt is scrapedScum to obtain a magnesium-aluminum-rare earth melt; then cooling the magnesium-aluminum rare earth melt to 640 ℃, adding the aluminum foil coated AlN/Al composite particles obtained in the step 2) into the magnesium-aluminum rare earth melt according to the mass percentage of 1.0 percent of the AE44 of the magnesium-aluminum rare earth alloy, pressing the aluminum foil coated AlN/Al composite particles to the bottom of the crucible for 40s by using a stirring spoon until the AlN/Al composite particles are released into the magnesium-aluminum rare earth melt and are completely coated by the magnesium-aluminum rare earth melt; mechanically dispersing the AlN/Al composite particles into the magnesium-aluminum-rare earth melt by adopting a blade type stirring paddle, wherein the stirring speed is 800rpm, mechanically stirring the AlN/Al composite particles back and forth at the middle upper part and the lower part of a crucible for 2min during mechanical stirring, and after the AlN/Al composite particles are completely immersed into the magnesium-aluminum-rare earth melt, stirring the AlN/Al composite particles at a fixed point in the middle of the crucible for 3min to uniformly disperse the AlN/Al composite particles into the magnesium-aluminum-rare earth melt to obtain a composite melt; after the mechanical stirring is finished, heating the composite melt to 680 ℃, placing a preheated ultrasonic stirrer in the composite melt, immersing an ultrasonic stirring head at a position 4-5cm above the liquid level, wherein the power is 200W, and the dispersion time is 5 min; and after the composite melt is uniformly dispersed by ultrasonic waves, removing floating slag on the surface of the composite melt, raising the temperature of the composite melt to 700 ℃, standing for 20min, and then condensing and solidifying water to obtain the AlN/Al particle reinforced magnesium-aluminum-rare earth based composite material.

In this example, the structure of the prepared AlN/Al particle-reinforced magnesium-aluminum-rare earth-based composite material is characterized, and as can be seen from fig. 6, compared with the magnesium-aluminum-rare earth alloy AE44 without adding AlN/Al composite particles, the microstructure of the composite material is also significantly refined, and the average grain size is about 375.1 μm; also, compared to example 2, the average grain size of the composite material tended to grow as the standing time increased from 5min to 20 min.

Comparative example 1

Commercial magnesium aluminum rare earth alloy AE44 was used as the matrix. At a volume ratio of 99: 1 CO₂And SF₆Under the protection of mixed gas, 1.5kg of magnesium-aluminum rare earth alloy AE44 is placed in a crucible to be heated along with a smelting furnace, the temperature is raised to 720 ℃ until the mixture is completely melted, the mixture is uniformly stirred, and scum on the surface of the melt is scraped to obtain a magnesium-aluminum rare earth melt; then casting the magnesium-aluminum rare earth melt into a metal mold for solidification and coolingHowever, the magnalium rare earth alloy is obtained, the structure of the magnalium rare earth alloy is characterized, and particularly as shown in fig. 2, the magnalium rare earth alloy can be seen from the figure that the crystal grains of the magnalium rare earth alloy are in a coarse dendritic shape; the grain size of the alloy was found to be about 1550 μm according to the Linear interpenet method.

Comparative example 2

The comparative example relates to an AlN/Al particle reinforced magnesium-aluminum-rare earth-based composite material, the components of the magnesium-aluminum-rare earth-based composite material are the same as those in example 3, the preparation method of the magnesium-aluminum-rare earth-based composite material is basically the same as that in example 3, except that in step 3), the volume ratio of the components is 99: 1 CO₂And SF₆Under the protection of mixed gas, 1.5kg of magnesium-aluminum rare earth alloy AE44 is placed in a crucible to be heated along with a smelting furnace, the temperature is raised to 720 ℃ until the mixture is completely melted, the mixture is uniformly stirred, and scum on the surface of the melt is scraped to obtain a magnesium-aluminum rare earth melt; then cooling the magnesium-aluminum rare earth melt to 650 ℃, adding the aluminum foil-coated AlN/Al composite particles obtained in the step 2) into the magnesium-aluminum rare earth melt according to 0.5 mass percent of the magnesium-aluminum rare earth alloy AE44, pressing the aluminum foil-coated AlN/Al composite particles to the bottom of the crucible for 60s by using a stirring spoon until the AlN/Al composite particles are released into the magnesium-aluminum rare earth melt and are completely coated by the magnesium-aluminum rare earth melt; mechanically dispersing the AlN/Al composite particles into the magnesium-aluminum-rare earth melt by adopting a blade type stirring paddle, wherein the stirring speed is 1000rpm, mechanically stirring the AlN/Al composite particles back and forth at the middle upper part and the lower part of a crucible for 4min during mechanical stirring, and after the AlN/Al composite particles are completely immersed into the magnesium-aluminum-rare earth melt, stirring the AlN/Al composite particles at a fixed point in the middle of the crucible for 4min to uniformly disperse the AlN/Al composite particles into the magnesium-aluminum-rare earth melt to obtain a composite melt; after the mechanical stirring is finished, heating the composite melt to 700 ℃, placing a preheated ultrasonic stirrer in the composite melt, immersing an ultrasonic stirring head in a position 4-5cm above the liquid level, wherein the power is 150W, and the dispersion time is 10 min; and after the composite melt is uniformly dispersed by ultrasonic waves, removing floating slag on the surface of the composite melt, raising the temperature of the composite melt to 700 ℃, standing for 30min, and then condensing and solidifying water to obtain the AlN/Al particle reinforced magnesium-aluminum-rare earth based composite material.

In this embodiment, the structure of the prepared AlN/Al particle-reinforced magnesium-aluminum-rare earth-based composite material is characterized, and it is found that, after 0.5% of AlN/Al composite particles are added to the magnesium-aluminum-rare earth alloy AE44 and the mixture is left standing for 30min, the grain size of the composite material cannot be significantly refined, compared with the magnesium-aluminum-rare earth alloy AE44 without particles, and the average grain size is about 863 μm; this is because, when the standing time is prolonged, the AlN ceramic particles in the composite material gradually settle to the bottom of the crucible due to the difference in density between the AlN ceramic particles and the magnesium matrix, thereby reducing the grain refining effect thereof.

Comparative example 3

The comparative example relates to an AlN/Al particle reinforced magnesium-aluminum-rare-earth-based composite material, the components of the magnesium-aluminum-rare-earth-based composite material are basically the same as those in example 3, the preparation method of the magnesium-aluminum-rare-earth-based composite material is the same as that in example 3, except that the step 3) is as follows: at a volume ratio of 99: 1 CO₂And SF₆Under the protection of mixed gas, 1.5kg of magnesium-aluminum rare earth alloy AE44 is placed in a crucible to be heated along with a smelting furnace, the temperature is raised to 720 ℃ until the mixture is completely melted, the mixture is uniformly stirred, and scum on the surface of the melt is scraped to obtain a magnesium-aluminum rare earth melt; then cooling the magnesium-aluminum rare earth melt to 650 ℃, adding the aluminum foil-coated AlN/Al composite particles obtained in the step 2) into the magnesium-aluminum rare earth melt according to 3 mass percent of magnesium-aluminum rare earth alloy AE44, and pressing the aluminum foil-coated AlN/Al composite particles to the bottom of the crucible for 60s by using a stirring spoon until the AlN/Al composite particles are released into the magnesium-aluminum rare earth melt and are completely wrapped by the magnesium-aluminum rare earth melt; mechanically dispersing the AlN/Al composite particles into the magnesium-aluminum-rare earth melt by adopting a blade type stirring paddle, wherein the stirring speed is 1000rpm, mechanically stirring the AlN/Al composite particles back and forth at the middle upper part and the lower part of a crucible for 4min during mechanical stirring, and after the AlN/Al composite particles are completely immersed into the magnesium-aluminum-rare earth melt, stirring the AlN/Al composite particles at a fixed point in the middle of the crucible for 4min to uniformly disperse the AlN/Al composite particles into the magnesium-aluminum-rare earth melt to obtain a composite melt; after the mechanical stirring is finished, heating the composite melt to 700 ℃, placing a preheated ultrasonic stirrer in the composite melt, immersing an ultrasonic stirring head in a position 4-5cm above the liquid level, wherein the power is 150W, and the dispersion time is 10 min; after the composite melt is dispersed uniformly by ultrasonic wave, the surface of the composite melt is scraped offAnd (3) floating slag, raising the temperature of the composite melt to 700 ℃, standing for 10min, and then condensing and solidifying water to obtain the AlN/Al particle reinforced magnesium-aluminum rare earth based composite material.

In this example, the structure of the prepared AlN/Al particle-reinforced magnesium-aluminum-rare earth-based composite material is characterized, and it is found that when 3% of AlN/Al composite particles are added to the magnesium-aluminum-rare earth alloy AE44, the grain size of the composite material cannot be significantly refined, compared with the magnesium-aluminum-rare earth alloy AE44 without particles, and the average grain size is about 1021 μm. This is because when the content of the particles is significantly increased, local agglomeration is easily caused during melting due to the large specific surface area of the nanoparticles, thereby reducing the grain refinement effect thereof.

Comprehensively, the AlN particle reinforced magnesium-aluminum rare earth based composite material is successfully prepared by a method of combining mechanical ball milling, mechanical stirring and ultrasonic stirring, the problem that AlN composite particles are difficult to wet with magnesium matrix alloy is solved, and the grain size of the magnesium-aluminum rare earth alloy AE44 is obviously refined; the preparation method of the AlN particle reinforced magnesium-aluminum rare earth-based composite material provided by the invention can avoid the combustion or oxidation of AlN particles, and the obtained composite material has compact structure, small grain size, no obvious interface reaction, excellent metallurgical quality and no obvious defect or impurity.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are also included in the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. The AlN/Al particle reinforced magnesium-aluminum-rare earth-based composite material is characterized by comprising the following components in percentage by mass: 99-99.9% of a magnesium matrix alloy and 0.1-1% of AlN/Al composite particles, the magnesium matrix alloy including Al: 4.17%, Mn: 0.36%, Si: 0.02 percent of RE, 3.99 percent of RE and the balance of Mg, wherein the RE is 50Ce-26La-15Nd-3 Pr.

2. The AlN/Al particle-reinforced magnesium-aluminum-rare earth-based composite material of claim 1, wherein the AlN/Al composite particles include AlN particles and Al particles, the AlN particles have a particle size of 40nm, the Al particles have a particle size of 10 μm, and a mass ratio of the AlN particles to the Al particles is 3: 1.

3. a method for preparing an AlN/Al particle-reinforced magnesium-aluminum rare earth-based composite material according to claim 1 or 2, comprising the steps of:

1) preparation of AlN/Al composite particles: mixing and ball-milling the AlN particles and the Al particles in percentage by mass in a star-shaped ball mill in a glove box protected by pure argon, and coating the ball-milled mixed material with aluminum foil after the ball-milling to prepare AlN/Al composite particles;

2) smelting and casting the magnesium-based composite material: adding the AlN/Al composite particles obtained in the step 1) into a magnesium-aluminum rare earth melt, and mechanically stirring to obtain a composite melt in which the AlN/Al composite particles are primarily dispersed; and (3) heating the composite melt to a liquidus temperature, further dispersing the composite melt by adopting ultrasonic waves, standing, preserving heat and solidifying by water condensation to obtain the AlN/Al particle reinforced magnesium-aluminum-rare earth based composite material.

4. The preparation method of the AlN/Al particle-reinforced magnesium-aluminum-rare earth-based composite material as claimed in claim 3, wherein the ball milling rotation speed is 80-120rpm and the ball milling time is 4-12h when the AlN particle and the Al particle are mixed and ball milled, and the mixture is left standing for 24-48h after the ball milling is completed.

5. The method for preparing the AlN/Al particle-reinforced magnesium-aluminum rare earth-based composite material according to claim 4, wherein the magnesium-aluminum rare earth melt is prepared by the following steps:

at a volume ratio of 99: 1 CO₂And SF₆Under the protection of mixed gas, magnesium base alloy is put into a crucible and heated along with a smelting furnace to 680-780 ℃ until the magnesium base alloy is completely melted, and then the magnesium base alloy is uniformly stirred andscraping the dross on the surface of the melt to obtain the magnesium-aluminum-rare earth melt.

6. The method for preparing the AlN/Al particle-reinforced magnesium-aluminum rare earth-based composite material as claimed in claim 5, wherein when the AlN/Al composite particles are added, the temperature of the magnesium-aluminum rare earth melt is reduced to 610-650 ℃, the mechanical stirring speed is 300-1000rpm, and the stirring time is 5-10 min.

7. The method of preparing the AlN/Al particle-reinforced magnesium-aluminum rare earth-based composite material of claim 6, wherein the mechanical stirring is: stirring back and forth for 2-5min at the middle upper part and the lower part of the crucible, and stirring for 3-5min at a fixed point at the middle position of the crucible after the AlN/Al composite particles are completely immersed into the magnesium-aluminum-rare earth melt.

8. The method for preparing the AlN/Al particle-reinforced magnesium-aluminum rare earth-based composite material according to claim 5, wherein the AlN/Al composite particles are added, and then the AlN/Al composite particles coated with the aluminum foil are pressed to the bottom of the crucible for 30-100s by using a stirring spoon until the AlN/Al composite particles are released into the magnesium-aluminum rare earth melt and are completely coated with the magnesium-aluminum rare earth melt.

9. The preparation method of the AlN/Al particle-reinforced magnesium-aluminum-rare earth-based composite material as claimed in claim 3, wherein the AlN/Al composite particles are added into the magnesium-aluminum-rare earth melt and mechanically stirred uniformly to obtain the composite melt, the temperature of the composite melt is raised to 680-720 ℃, the composite melt is dispersed by using ultrasonic waves, the power of the ultrasonic waves is 150-300W, and the dispersion time is 5-10 min.

10. The method for preparing the AlN/Al particle-reinforced magnesium-aluminum-rare earth-based composite material according to claim 9, wherein after the composite melt is uniformly dispersed by ultrasonic waves, scum on the surface of the composite melt is removed, and after the composite melt is kept at 700 ℃ and is kept standing for 5-20min, water is condensed and solidified.

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